Nikolaos Mellios, Mriganka SurPublished:4 March 2014
RNA acts as the intermediary between genes and proteins, but the function of pieces of RNA that do not code for protein has, historically, been less clear.Researchers have ignored these noncoding RNAs until recently for not complying with the central dogma of biology — that a straight line runs from gene to RNA (transcription) to protein (translation). However, noncoding RNAs are emerging as important regulators of diverse cellular processes with implications for numerous human disorders.
Extensive research has already examined the function of microRNAs, a category of small evolutionarily conserved noncoding RNAs about 22 to 24 nucleotides in length that target protein-coding genes in a sequence-specific manner. A plethora of microRNAs are important for brain function and neuropsychiatric diseases, including autism1.
In the past decade, long noncoding RNAs (lncRNAs), which extend longer than 200 nucleotides, have emerged as additional important players in the control of gene expression. They fine-tune the expression of numerous genes and direct the activity of complex regulatory pathways, often in a cell- and developmental-stage-specific manner.
They are found in many places in the genome: within genes, near gene regulatory regions or by themselves (intergenic noncoding RNAs). lncRNAs may overlap with the genetic code for a protein or be expressed in the opposite, or antisense, direction.
In addition to the diversity in their biogenesis, lncRNAs exhibit an impressive versatility of molecular functions. These range from passive influence on the transcription of nearby genes to limiting expression to a paternal or maternal chromosome, a process called imprinting, and inactivating one copy of the X chromosome.
They also interact with chromatin-modifying complexes, which regulate gene expression by changing the packaging of DNA, and with transcription factors that directly regulate gene expression. They may influence RNA splicing, stability and localization and play a role in the translation of RNA to protein and in protein activation. Finally, they may ‘sponge’ up certain microRNAs, thus blocking their function2, 3, 4, 5.
The ability of lncRNAs to engage in such molecular multitasking may allow them to link multiple risk factors for genetic disorders into functional networks. This makes them attractive candidates for autism spectrum disorders, which are characterized either by interactions of multiple genes or by disruptions in a single gene that influences numerous molecular pathways.
Whether whole-genome DNA sequencing data will reveal strong genetic links with lncRNAs, as it has for microRNAs, is not yet clear. One thing, though, remains certain: We can no longer overlook such a substantial and active chunk of the transcriptome and characterize it as ‘junk’ or ‘transcriptional noise’ if we hope to fully understand complex disorders such as autism.
In the past few years, studies have found alterations in lncRNAs in brains from people with autism, suggesting that they contribute to autism risk. For example, MSNP1AS, a lncRNA transcribed from a region of chromosome 5 that carries an autism-associated variant, is elevated in the cortex of people with autism who also carry the disease-related variant6. MSNP1AS may regulate moesin, a gene important for the structure of neurons’ signal-receiving branches, or dendrites, and immune system activation.
Last year, a carefully conducted study identified numerous lncRNAs that are robustly dysregulated in autism postmortem brain samples7. Impressively, some disease-altered lncRNAs are found near important autism-linked genes such as BDNFand SHANK2.
Another lncRNA with potential implications for autism is LOC389023, which regulates DPP10, a gene linked to autism and other neurodevelopmental disorders. DPP10 controls the structure and function of neuronal junctions, or synapses, via its effects on potassium ion channels3.
Last year, researchers used a similar approach to study the expression of lncRNAs in a mouse model of Rett syndrome8. One lncRNA (AK081227) that is expressed at abnormal levels in these mice controls the expression of its host protein-coding gene, the gamma-aminobutyric acid receptor subunit Rho 2 (GABRR2), which has also been linked to autism.
Additional reports have linked other lncRNAs to autism, such those that travel antisense to the FMR19, 10 and UBE3A11, 12genes. Mutations in these genes underlie fragile X syndrome and Angelman syndrome, respectively. Other studies have also uncovered a subset of lncRNAs expressed from the autism-linked PTCHD1 gene13 and the 7q31 chromosomal region14.
In addition, the lncRNA ZNF127AS has altered expression in the brains of people with Prader-Willi syndrome15. On a similar note, a cluster of small nucleolar RNAs — which despite their name are a category of lncRNAs — are encoded by the paternally inherited microdeletion at 15q11.2 that is also linked to Prader-Willi syndrome16.
Previous work has identified a subset of lncRNAs that are important for regulating the birth of new neurons, or neurogenesis, and the process by which synapses adapt to experience, called synaptic plasticity.
Of particular importance is the finding that the intergenic noncoding RNA MALAT1, one of the most highly expressed lncRNAs in the brain, can regulate the formation of new synapses, or synaptogenesis. It does this by associating inside the nucleus with multiple RNA splicing factors and influencing the expression of autism-linked genes, such as NLGN117.
Intriguingly, there are several other links between MALAT1 and autism-associated factors. For example, beta-catenin — an important component of the WNT signaling pathway that has been linked to multiple neuropsychiatric disorders — activates MALAT1 transcription18. CREB, another transcription factor known for its role in activity-dependent gene expression, also binds to MALAT1. Notably, CREB may control MALAT1 transcription following exposure to the peptide hormone oxytocin, which has also been linked to autism19.
MALAT1 and another lncRNA, BDNFOS, which has the antisense, or opposite, code to that of the autism-linked BDNF gene, are expressed in conjunction with neuronal activity20. On the other hand, GOMAFU, a lncRNA whose levels are dampened in postmortem brains from people with schizophrenia, is significantly suppressed following the activation of mouse cortical neurons21.
Other lncRNAs run antisense to important synaptic plasticity-related genes, such as NRGN, CAMK2N1 and CAMKK122, 23. lncRNAs are also associated with genes linked to changes in the synapse that occur after exposure to cocaine24. Interestingly, a novel subset of lncRNAs are expressed from the regulatory elements of genes, such as c-FOS and ARC, that regulate gene transcription in response to neuronal activity25.
Adding to their important role in brain plasticity, lncRNAs are highly expressed during prenatal neurogenesis and are important for maintaining and differentiating the precursors to neurons: neural stem cells and neuronal progenitors26, 27. Of particular interest is the lncRNA EVF2, which runs antisense to the regulator gene DLX5,6 and plays a crucial role in the birth of neurons that dampen brain activity28. This adds another layer to the role of lncRNAs in cell-type-specific neuronal functions.
Despite these many threads, much more work is needed to determine the exact mechanisms of action and the physiological significance of lncRNAs for autism and other neurodevelopmental disorders.
Mriganka Sur is professor of neuroscience at the Massachusetts Institute of Technology, in Cambridge. Nikolaos Mellios is a postdoctoral fellow in his laboratory.
News and Opinion articles on SFARI.org are editorially independent of the Simons Foundation.
1. Mellios N. and M. Sur Front. Psychiatry 3, 39 (2012) PubMed
2. Qureshi I.A. and M.F. Mehler Nat. Rev. Neurosci. 13, 528-541 (2012) PubMed
3. Tushir J.S. and S. Akbarian Neuroscience Epub ahead of print (2013) PubMed
4. Mercer T.R. and J.S. Mattick Nat. Struct. Mol. Biol. 20, 300-307 (2013) PubMed
5. Bak R.O. and J.G. Mikkelsen Wiley Interdiscip. Rev. RNA Epub ahead of print (2013) PubMed
6. Kerin T. et al. Sci. Transl. Med. 4, 128ra40 (2012) PubMed
7. Ziats M.N. and O.M. Rennert J. Mol. Neurosci. 49, 589-593 (2013) PubMed
8. Petazzi P. et al. RNA Biol. 10, 1197-1203 (2013) PubMed
9. Ladd P.D. et al. Hum. Mol. Genet. 16, 3174-3187 (2007) PubMed
10. Pastori C. et al. Hum. Genet. 133, 59-67 (2014) PubMed
11. Chamberlain S.J. and C.I. Brannan Genomics 73, 316-322 (2001) PubMed
12. Le Meur E. et al. Dev. Biol. 286, 587-600 (2005) PubMed
13. Noor A. et al. Sci. Transl. Med. 2, 49ra68 (2010) PubMed
14. Vincent J.B. et al. Genomics 80, 283-294 (2002) PubMed
15. Jong M.T. et al. Hum. Mol. Genet. 8, 783-793 (1999) PubMed
16. Sahoo T. et al. Nat. Genet. 40, 719-721 (2008) PubMed
17. Bernard D. et al. EMBO J. 29, 3082–3093 (2010) PubMed
18. Wang J. et al. Cell Signal. 26, 1048-1059 (2014) PubMed
19. Koshimizu T.A. et al. Life Sci. 86, 455-460 (2010) PubMed
20. Lipovich L. et al. Genetics 192, 1133-1148 (2012) PubMed
21. Barry G. et al. Mol. Psychiatry Epub ahead of print (2013) PubMed
22. Ling K.H. et al. Cereb. Cortex 21, 683-697 (2011) PubMed
23. Mercer T.R. et al. Neuroscientist 14, 434-445 (2008) PubMed
24. Bu Q. et al. J. Neurochem. 123, 790-799 (2012) PubMed
25. Kim T.K. et al. Nature 465, 182-187 (2010) PubMed
26. Ng S.Y. et al. EMBO J. 31, 522-533 (2012) PubMed
27. Sauvageau M. et al. Elife 2, e01749 (2013) PubMed
28. Bond A.M. et al. Nat. Neurosci. 12, 1020-1027 (2009) PubMed